Fluoroscopic image guided surgery system with intraoperative registration

ABSTRACT

A system and apparatus allows the tracking of a selected body portion, instrument, or both. A tracking device can be interconnected to a body portion at a mounting site. A procedure can be performed at a location remote from the mounting site of the tracking device. The tracking device can be interconnected with the body in a low invasive manner.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation of U.S. patent application Ser. No. 10/230,958, filed on Aug. 29, 2002; which is a continuation of U.S. patent application Ser. No. 09/376,712, filed on Aug. 16, 1999, now U.S. Pat. No. 6,477,400; which claims the benefit of both U.S. Provisional Application Ser. No. 60/097,742, filed on Aug. 24, 1998 and U.S. Provisional Application Ser. No. 60/097,183, filed on Aug. 20, 1998. The disclosures of which are hereby incorporated by reference.

BACKGROUND OF THE INVENTION

In orthopaedic surgery it is often necessary to insert a guide pin for a cannulated screw, drill bit, or other screw (hereafter referred to as a fixation device) into a bone at a predetermined trajectory. Pre-operative planning depends on two-dimensional radiographic images which typically consist of two views taken at approximately right angles to one another. From these two views it is possible to determine the shape and structure of a long bone. Using that method, the path of insertion for a guide pin for a cannulated screw, drill bit, or screw is accurately determined. However, in practice the actual aiming of a fixation device is an inaccurate art, as the object bone is often seen only at one surface or is not seen at all and, therefore, positioning is dependent on fluoroscopic visualization. This method is also time consuming as the C-arm images must be taken separately and the drapes must be rearranged each time an image is taken. As boney tissue is unyielding, the track of the pin or drill bit is determined by the angular approach before entering the object bone. This angular approach is difficult to determine under normal circumstances and often multiple attempts are needed, as feedback is obtained from repeated fluoroscopic images. Existing methods of calculating the proper angle of guide pin for a cannulated hip screw insertion for hip pinning involve placing data manually into a computer program, which in turn outputs an angle of guide pin for a cannulated hip screw insertion.

Radiation exposure is a necessary part of any procedure for calculating the proper angle of a guide pin, drill bit, or screw insertion. Radiation exposure is considered to be a hazard. Ionizing radiation has no safe threshold of exposure below which it ceases to have adverse effects, although an arbitrary level is assumed. There has been a recent upward revision of risk estimates of radiation exposure, but absolute levels of safe exposure remain unknown. Exposure to the surgical team as well as the patient during orthopaedic procedures using fluoroscopy is a universal concern. Consequently, a reduction in the amount of radiation exposure is highly desirable.

Operative stereotactic localization using either frames or three-dimensional digitizers is currently being used in neurosurgery or otoloaryngology. Those methods require the use of computed axial tomography (CT) or magnetic resonance imaging (MRI) prior to surgery. They also involve placing markers on the scalp prior to the imaging study of the head. The markers must be left in the same position until surgery is performed in order to confirm intraoperative registration. Such imaging studies are routinely performed for most intracranial procedures but are impractical for most orthopaedic procedures, especially those involving long bones. A probe marked with light emitting diodes (LEDs) or other digitizing emitters is used to localize these markers or pins using a three-dimensional digitizing device at the time of surgery. A disadvantage of this system is that the images are normally obtained hours before use; thus, the images used are not up to date (real time) and are often not reflective of the current condition of the object bone.

Registration markers cannot be used on the outside of the body in most orthopaedic cases as the skin does not adhere to the underlying bone. Pre-operative registration for robotic placement of the femoral components for total hip arthroplasty requires the use of a separate procedure to insert screws for such markers. Such a separate procedure is highly impractical for routine orthopaedic procedures.

An alternative method of registration for image guided surgery requires wide operative exposure, such as in pedicle screw insertion in spine surgery. The various fiducials are determined by touching prominent or distinctive anatomic points with a digitizing probe as employed by the stereotactic localization system. Furthermore, the system also requires preoperative computed axial tomography.

A system using fluoroscopic images to guide the insertion of a fixation device employs tracking with a three-dimensional optical digitizer. This optical digitizer is used to determine the position in six degrees of freedom of a portable fluoroscopy machine (“C-arm fluoroscope”) and the object region of the skeleton. Light emitting diodes (“LEDs”) are placed in distinctive patterns on the C-arm. Another set of LEDs are attached to the bone with a percutaneous screw device, such as a reference bar. A computer program records these positions in relation to an optical position sensor.

X-rays are then taken with the C-arm fluoroscope with the two positions of the tube at approximate right angles to one another. The optical position sensor can thus determine where the C-arm is positioned in relation to LED markers attached to the reference bar attached to the object section of the skeleton. The exact position is determined by using two-dimensional image registration, matching the outline of the bone in two planes. In this system, three or more distinctly shaped radiographic markers are attached to threaded tipped registration pins inserted percutaneously. Thus, the object portion of the skeleton is localized in six degrees of freedom by the optical digitizer.

The computer program relates the position of the object bone with or without fiducial markers in the two fields to determine the exact relative position of the object bone seen on the two images. Once those two images are displayed on monitors, no further x-rays are needed. Thus, a substantial reduction in the amount of ionizing radiation results. The images displayed are those familiar to the surgeon but with the usual distortion eliminated.

A drill with attached LEDs inserts the fixation device in the position in the bone that the surgeon chooses based on the supplied information. The three-dimensional optical digitizer determines the position of the drill in relation to the optical digitizer camera and the object section of the skeleton with its fiducials. A graphic display of the fixation device of predetermined length is then overlaid on the images of the object bone in near real time. Thus, the position of the inserted pin or drill bit can be adjusted immediately.

SUMMARY OF THE INVENTION

The present invention allows an orthopaedic surgeon to safely determine the precise trajectory of insertion of a fixation device into an object bone and to check the accuracy of the procedure using real time feedback.

The present invention remedies the disadvantages of the prior art system of using fluoroscopic images and an optical digitizer to localize the object bone and the track of the intended fixation device.

The same three-dimensional optical digitizer is used to determine the position in six degrees of freedom of a portable fluoroscopy machine (C-arm fluoroscope) and the object regional of the skeleton. Light emitting diodes (LEDs) are placed in distinctive patterns on the C-arm and attached to the bone, the latter with a percutaneous screw device, such as a reference bar. A computer program records these positions in relation to an optical position sensor.

X-rays are then taken with the C-arm fluoroscope with the two positions of the tube at approximate right angles to one another. The optical position sensor can thus determine where the C-arm is positioned in relation to LED markers attached to the reference bar attached to the object section of the skeleton. The exact position is determined by using two-dimensional image registration, matching the outline of the bone in two planes.

The difference from prior art is that, in this invention, distinctly shaped radiographic markers are not required to match the position of the object bone with the image thereof. Matching, or registration, is performed by a single registration pin or other object that is seen on both x-ray views. The spherical shape of the femoral head may be used to increase the accuracy of the registration if the invention is used for hip surgery. When used for inserting distal locking screws for intramedullary nails, the presence of the nail alone with the holes for the interlocking screws can be used as fiducial reference marker. This method of image registration is clearly superior to the use of three special registration pins with specialized markers.

The fixation device can then be inserted using a drill or drill guide that has attached LEDs that serve as means to localize it in six degrees of freedom. The graphic representation of the guide pin for a cannulated screw, drill bit, or extended projection of the drill guide positioned appropriately on the pair of monitors can be used to determine the correct trajectory.

Accurate localization of a hip screw in the femoral head has been shown in an important clinical study to result in much superior results than if the screw is placed eccentrically. Accurate aiming of an interlocking screw in an intramedullary nail is difficult to obtain using all current techniques. It is improved by this invention such that operative time and radiation are markedly reduced.

This invention has the advantage of simplifying the operation and making it more acceptable to use computer assisted surgery to improve accuracy.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is an illustration of anterior and lateral x-ray views of the proximal femur with an intertrochanteric fracture with a hip screw in optimal position.

FIGS. 2A & 2B are perspective illustrations of the intraoperative setting showing the C-arm fluoroscope, an optical digitizer camera, and the object body.

FIG. 3 is an illustration of a drill with mounted light emitting diodes.

FIG. 4 is an illustration of a pair of computer monitor screens with radiographic images of the object bone at positions approximately 90 degrees to one another, with a single registration pin and a reference bar in place, and with the graphic image of a guide pin 302 for a cannulated hip screw superimposed.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

The operation for the internal fixation of intertrochanteric hip fracture 100 requires a guide pin for a cannulated hip screw, and subsequently cannulated screw 101, to be placed into femoral head 102 from lateral cortex 103 of proximal femur 220 via femoral neck 104, as illustrated in FIG. 1. Guide pin 302 for cannulated hip screw 101 determines the position of cannulated screw 101. The ideal position of the guide pin for a cannulated hip screw, and thus screw 101, is entirely within bone. The end of the pin, and screw 101, is best positioned very near the subcortical bone but should not penetrate the cortex and thus enter the hip joint. The best results of an intertrochanteric fracture 100 must have been shown to occur when large screw 101 used is in the center of the femoral head at the subcortical bone. This position is normally obtained by placing the guide pin for a cannulated hip screw by estimation and by following its course on entry with repeated x-rays views in two planes. C-arm fluoroscope 200, as seen in FIG. 2, must be moved from one position of the other. Repeated attempts may be needed before the optimal position of guide pin 302, as seen in FIG. 4, for a cannulated hip screw can be obtained. Operating time and radiation exposure would be reduced by using image guided surgery. The accuracy and thus long term results would be improved.

In this system of fluoroscopic image guided orthopaedic surgery with intraoperative registration, light emitting diodes (LEDs) are attached to portable C-arm fluoroscopy 200 at two sites. One LED 201 is placed to determine the position of C-arm 200 when in the upright position as in FIG. 2A, which corresponds to the anteroposterior x-ray view when the patient 205 is supine. Another LED 202 is located so that it is seen by optical digitizer camera 212 when C-arm 200 is horizontal as in FIG. 2B, corresponding to the lateral x-ray view.

Patient 205 is lying supine in traction on a fracture table during the procedure. After appropriate sterile preparation, reference bar 210 with LEDs is inserted through a small incision into ilium 218. The optical digitizer software is programmed to recognize the region of the skeleton attached to reference bar 210 as a rigid body. The rigid body computer model thus remains immobile, and the other objects with LEDs attached move in relation to this rigid body. Femur 220 must remain immobile in relation to ilium 218, which is usually the case. FIG. 4 illustrates x-ray views seen with the fluoroscope.

Then proximal femur 220 is exposed through a routine lateral incision. Registration pin 215 is then inserted in proximal femur 220. X-rays at approximate right angles are then taken in the standard anteroposterior and lateral views. When C-arm 200 is in the upright position (FIG. 2A), LEDs 201 facing optical digitizer camera 212 indicate to the computer where C-arm 200 is in three dimensional space. Thus the computer can calculate the plane in which body 205 lies—in relation to reference bar 210. When C-arm 200 is in the horizontal position (FIG. 2B), LEDs 202 are now facing optical digitizer camera 212 and indicate again where C-arm 200 is in three dimensional space when in this position. The computer can then calculate exactly where body 205 and femur 220 seen on x-ray are in relation to optical digitizer camera 212. This calculation is possible with registration pin 215 and femur 220 now being recorded in two positions. The method of finding the position of registration pin 215 is a type of image registration.

LEDs 300 are mounted on the body of drill 301 as shown in FIG. 3. Guide pin 302 for cannulated hip screw 101 is placed in position into drill 301.

The signals emitted from LEDs 300 on drill 301 are received by optical digitizer camera 212 when placed in the operating field. The computer can then determine the position of drill 301 to reference bar 210 and thus to femur 220. A graphic image of guide pin 302 for a cannulated hip screw can then be displayed on each monitor 400 as seen in FIG. 4 to show the relationship of guide pin 302 for a cannulated hip screw to femur 220 in both the anteroposterior and the lateral views. Guide pin 302 for cannulated hip screw 101 can then be inserted in the desired position with image guidance.

If reference bar 210 should be moved or loosened, registration can be done again during the operation just be repeating the two x-ray views. Once registration pin 215 is in place, identification of fiducials by the tedious method of touching points with a probe is unnecessary. The accuracy of image registration with registration pin 215 or other object is much greater than with previous methods. 

1. A method of performing a guided surgical procedure on an anatomy, comprising: inserting a reference bar into a location on a portion of a pelvis of the anatomy; exposing a region of the anatomy remote from the location of the reference bar; performing a procedure on a portion of the anatomy remote from the location of the reference bar; and determining a location of an instrument relative to the reference bar.
 2. The method of claim 1, wherein inserting a reference bar includes; sterilizing an appropriate portion of the anatomy; forming a small incision in the anatomy relative to the sterilized appropriate portion of the anatomy; and inserting the reference bar through the small incision.
 3. The method of claim 2, wherein inserting the reference bar includes positioning the reference bar in the illium defined by the pelvis.
 4. The method of claim 1, further comprising: obtaining image data of the anatomy; and registering the position of the reference bar to the obtained image data of the anatomy.
 5. The method of claim 4, wherein determining the location of the instrument includes tracking the instrument relative to the reference bar.
 6. The method of claim 5, further comprising: displaying a position of the instrument relative to the image data based upon the tracked position of the instrument.
 7. The method of claim 6, further comprising: fusing a first portion and a second portion wherein at least one of the first portion or the second portion form a joint with a portion of the pelvis.
 8. The method of claim 6, further comprising: fusing a first portion of the anatomy to a second portion of the anatomy wherein at least one of the first portion or the second portion is near a portion of the pelvis.
 9. The method of claim 7, wherein performing a procedure on a portion of the anatomy remote from the location of the reference bar includes: registering the reference bar to the obtained image data; tracking the instrument relative to the reference bar; and moving the instrument relative to the portion of the anatomy remote from the location of the reference bar.
 10. The method of claim 9 further comprising: interconnecting a first bone portion and a second bone portion relative to the pelvis; and wherein tracking the instrument includes tracking and positioning a member to interconnect the first bone portion and the second bone portion.
 11. The method of claim 9, further comprising: holding the bone portion relative to the pelvis to determine a position of the bone portion relative to the pelvis based at least in part upon the position of the bone portion relative to the reference bar on the pelvis.
 12. The method of claim 1, further comprising: a system operable to determine a location of the reference bar in three dimensional space; and wherein determining the location of the instrument includes providing a signaling device to be tracked by the system.
 13. The method of claim 1, further comprising: positioning a registration member in the anatomy remote from the location of the reference bar; obtaining image data of the portion of the anatomy remote from the location of the reference bar; and registering the registration member with the obtained image data.
 14. The method of claim 1, wherein determining a location of an instrument relative to the reference bar includes tracking a bone screw.
 15. The method of claim 14, wherein determining a location of an instrument relative to the reference bar includes tracking a drill driving the bone screw.
 16. The method of claim 1, wherein determining a location of an instrument relative to the reference bar includes tracking a drill.
 17. The method of claim 1, further comprising: obtaining image data of the anatomy.
 18. The method of claim 17, wherein obtaining image data of the anatomy includes obtaining image data from at least two planes relative to the anatomy.
 19. A method of performing a guided surgery on a portion of the anatomy, comprising: sterilizing an appropriate portion of the anatomy; inserting a reference bar through a small incision relative to the sterilized portion; attaching the reference bar to a portion of the pelvis; and performing a fixation procedure on a portion of the anatomy remote from the pelvis.
 20. The method of claim 19, wherein sterilizing an appropriate portion of the anatomy includes: selecting a portion of the anatomy for attachment of the reference bar; sterilizing the area of the anatomy near the area for attaching the reference bar; and inserting the reference bar through the small incision to attach it to the selected portion of the anatomy.
 21. The method of claim 19, wherein sterilizing an appropriate portion of the anatomy includes draping a selected portion of the anatomy.
 22. The method of claim 21, wherein sterilizing an appropriate portion of the anatomy includes arranging a drape in preparation of obtaining image data of the patient.
 23. The method of claim 19, further comprising: exposing a portion of the anatomy after attaching the reference bar to the portion of the pelvis; and performing the fixation procedure through the exposed portion of the anatomy after attaching the reference bar.
 24. The method of claim 19, wherein performing a fixation procedure remote from the pelvis includes performing a procedure on a bone portion that articulates with a portion of the pelvis.
 25. The method of claim 24, wherein performing a procedure on a bone portion that articulates with the pelvis includes performing a procedure on a femur in the anatomy.
 26. The method of claim 24, wherein performing a procedure on a bone portion that articulates with the anatomy includes interconnecting two bone portions.
 27. The method of claim 26, wherein the two bone portions include a femoral head a body of the femur, wherein the femoral head has fractured from the body of the femur.
 28. The method of claim 19, wherein performing a fixation procedure on a portion of the anatomy remote from the pelvis includes fixing a first bone portion to a second bone portion.
 29. The method of claim 28, wherein a screw is positioned to fix the first bone portion to the second bone portion and the screw is contained entirely within the first bone portion, the second bone portion, or combinations thereof.
 30. The method of claim 19, where inserting a reference bar includes: selecting a reference bar including L.E.D.'s; and inserting the reference bar so at least the L.E.D.'s are viewable by a camera system.
 31. The method of claim 19, further comprising: providing a system operable to determine the location of the reference bar; tracking an instrument with the system; and determining a position of the instrument relative to the reference bar.
 32. The method of claim 31, wherein determining a position of the instrument relative to the reference bar includes performing the fixation procedure in a guided manner.
 33. The method of claim 32, further comprising: displaying on a display an image of the portion of the anatomy remote from the pelvis.
 34. A method of performing an image guided surgery on an anatomy, comprising: obtaining image data of a region of the anatomy; attaching a reference bar to a portion of the region of the anatomy wherein attaching the reference bar includes attaching the reference bar to a first bone portion defining a first portion of a joint; selecting a second bone portion in the anatomy defining a second portion relative to the joint; and guiding a member relative to the second bone portion.
 35. The method of claim 34, wherein the first portion of the joint is a portion of the pelvis; and wherein the second bone portion includes a bone portion operable to articulate with the pelvis.
 36. The method of claim 34, wherein attaching a reference bar to a portion of the region of the anatomy includes attaching a reference bar to an illium in the anatomy.
 37. The method of claim 34, further comprising: determining a location of the member in three dimensional space relative to the reference bar; determining a position of the second bone portion relative to the member; and tracking the member relative to the second bone portion.
 38. The method of claim 37, wherein determining the position of the second bone portion includes determining a position of the second bone portion relative to the reference bar attached to the portion of the region of the anatomy.
 39. The method of claim 34, further comprising: inserting a fixation screw through a portion of a femur to interconnect the femoral head and the body of the femur.
 40. The method of claim 34, wherein guiding a member includes ensuring that the member is completely within the first bone portion, the second bone portion, or combinations thereof. 